dipeptides

dipeptide bonds are essential for maintaining the three-dimensional structure of proteins.

enzymatic dipeptide synthesis occurs under mild physiological conditions in living cells.

the dipeptide concentration in blood plasma can be accurately measured using chromatographic techniques.

dipeptide hydrolysis is catalyzed by specific peptidases during protein digestion.

scientists have developed novel dipeptide derivatives with improved pharmacological properties.

specific dipeptide sequences function as important signaling molecules in cellular communication.

some dipeptide mimetics exhibit potent inhibitory activity against target enzymes.

membrane transporters facilitate dipeptide absorption across the intestinal epithelium.

elevated dipeptide levels in urine may serve as biomarkers for certain diseases.

the dipeptide structure was elucidated using advanced spectroscopic methods.

dipeptide-based nanocarriers enable targeted drug delivery to specific tissues.

dipeptide metabolism involves multiple enzymatic pathways distributed throughout the body.

small dipeptide molecules can penetrate the blood-brain barrier more efficiently.